Asymptotic solutions of the nonlinear Boltzmann equation for dissipative systems

TL;DR

This paper derives asymptotic solutions for the nonlinear Boltzmann equation in dissipative systems, revealing overpopulated high-energy tails and their dependence on interaction parameters, with implications for stability and kinetic modeling.

Contribution

It introduces a unified analysis of asymptotic solutions for a class of dissipative models, including inelastic repulsive scatterers, and compares kinetic equations' predictions with full Boltzmann solutions.

Findings

Overpopulated high-energy tails described by stretched Gaussians.

Power law tails occur only in marginal cases, determined by transcendental equations.

Stability thresholds depend on thermostat type, with free cooling at =0.

Abstract

Analytic solutions $F(v,t)$ of the nonlinear Boltzmann equation in $d$-dimensions are studied for a new class of dissipative models, called inelastic repulsive scatterers, interacting through pseudo-power law repulsions, characterized by a strength parameter $\nu$, and embedding inelastic hard spheres ($\nu=1$) and inelastic Maxwell models ($\nu=0$). The systems are either freely cooling without energy input or driven by thermostats, e.g. white noise, and approach stable nonequilibrium steady states, or marginally stable homogeneous cooling states, where the data, $v^d_0(t) F(v,t)$ plotted versus $c=v/v_0(t)$, collapse on a scaling or similarity solution $f(c)$, where $v_0(t)$ is the r.m.s. velocity. The dissipative interactions generate overpopulated high energy tails, described generically by stretched Gaussians, $f(c) \sim \exp[-\beta c^b]$ with $0 < b < 2$, where $b=\nu$ with $\nu>0$ in free cooling, and $b=1+{1/2} \nu$ with $\nu \geq 0$ when driven by white noise. Power law tails, $f(c) \sim 1/c^{a+d}$, are only found in marginal cases, where the exponent $a$ is the root of a transcendental equation. The stability threshold depend on the type of thermostat, and is for the case of free cooling located at $\nu=0$. Moreover we analyze an inelastic BGK-type kinetic equation with an energy dependent collision frequency coupled to a thermostat, that captures all qualitative properties of the velocity distribution function in Maxwell models, as predicted by the full nonlinear Boltzmann equation, but fails for harder interactions with $\nu>0$.